EP0381309A2

EP0381309A2 - Signal extraction apparatus and method

Info

Publication number: EP0381309A2
Application number: EP90300101A
Authority: EP
Inventors: Alan James Cook
Original assignee: Lucas Industries Ltd
Current assignee: ZF International UK Ltd
Priority date: 1989-01-06
Filing date: 1990-01-04
Publication date: 1990-08-08
Anticipated expiration: 2010-01-04
Also published as: US5115128A; EP0381309B1; GB8900304D0; EP0381309A3; DE69014658T2; DE69014658D1; JPH03197817A

Abstract

A resonant beam sensor (1, 10, 34) is excited into resonance by directing onto it a drive signal comprising light which has been amplitude modulated at the resonant frequency. A portion of the drive signal reflected by the sensor (1, 10, 34) is demodulated by a photodetector (15, 32) to provide a measurement signal.

Description

The present invention relates to a signal extraction apparatus and method. Such an apparatus may be used to extract a measurement signal from a drive signal for a transducer.
A known type of transducer is the so-called oscillating or resonant beam transducer which is forced into oscillation at its resonant frequency by the impingement of light which has been amplitude-modulated at the resonant frequency of the beam.
In order to provide a useful measurement signal, light of a particular optical wavelength is first amplitude modulated by drive elements at the resonant frequency of the beam and is then directed onto the beam. The resonant beam is thus caused to oscillate at its resonant frequency by the modulated "drive" light.
Another light source produces continuous or D.C. light of a different optical wavelength and this "detecting" light is directed towards the beam where it is amplitude modulated by movement of the beam. The reflected detecting light can be extracted from the reflected drive light by an optical wavelength filter because of the difference in optical wavelength. The extracted amplitude modulated detecting light is then directed onto a photodetector which provides an output representing the oscillating beam movement.
Although this arrangement works very well, it does require the presence of two light sources of different optical wavelengths which makes the arrangement somewhat expensive. Also, for convenience, a single optical fibre is used to transmit light from both sources to the oscillating beam and to return the reflected light to the photodetector. This requires the presence of two optical splitters, one being a beam splitter or Y-coupler and the other being a wavelength filter, which makes the arrangement expensive and cumbersome. The cost and complexity of this arrangement therefore precludes the use of transducer arrangements of this type in many applications which would otherwise be attractive.
According to a first aspect of the invention, there is provided a signal extraction apparatus, comprising means for generating a drive signal comprising a carrier signal amplitude modulated by a modulating signal, and coupling means for coupling the drive signal to a resonant sensor whose resonant frequency is substantially equal to the frequency of the modulating signal, characterised by a demodulator for demodulating a portion of the drive signal reflected by the sensor.
The carrier signal is preferably light and the index of modulation is preferably less than 100% so that the drive signal is an uninterrupted light signal.
It is thus possible to provide an extraction apparatus which allows the transducer signal to be extracted from the return signal, despite having the same frequency as the modulating signal. Such an arrangement may be used with a resonant or oscillating beam transducer as the resonant sensor with the generating means comprising a light source whose output never falls to zero.
Only a single light source is necessary and this allows the cost and complexity of the transducer arrangement to be reduced to a level where the arrangement finds much wider application than with previously known arrangements. The coupling means is preferably an optical fibre and the demodulator is preferably a photodetector coupled to the optical fibre to receive light reflected from the resonant device. A single beam splitter such as a Y-coupler is thus sufficient, and allows the cost and complexity of the transducer arrangement to be reduced as compared with previously known arrangements. In some applications, it may be desirable for a second photodetector to be coupled to the optical fibre so as to receive the modulated light and to supply the modulating signal to subtracting means However, in general where substracting means is provided, it is preferred that the subtracting means receives the modulating signal direct, thus avoiding the cost and complexity of a second photodetector and a second beam splitter.
The signal extraction apparatus may, of course, be used with other forms of carrier signal, such as other parts of the electromagnetic spectrum or ultrasound.
According to a second aspect of the invention, there is provided a method of signal extraction, comprising directing onto a resonant sensor a drive signal comprising a carrier signal amplitude modulated by a modulating signal of frequency substantially equal to the resonant frequency of the sensor, and demodulating a portion of the drive signal reflected by the sensor.
The invention will be further described, by way of example, with reference to the accompanying drawings, in which:

Figure 1 is a schematic block diagram of a first general embodiment of the invention;
Figure 2 is a schematic block diagram of a first preferred embodiment of the invention;
Figure 3 is a more detailed block diagram of a second preferred embodiment of the invention;
Figure 4 illustrates a type of resonant beam transducer with which signal extraction apparatus may be used; and
Figure 5 is a block diagram of a third preferred embodiment of the invention.

The signal extraction apparatus shown in Figure 1 is coupled to a resonant device 1 which may be any device arranged to oscillate at a resonant frequency when supplied by a drive signal in the form of a carrier signal amplitude modulated by a modulating signal whose frequency is equal to the resonant frequency of the device 1. A drive signal generator 2 supplies a suitable drive signal via coupling means 3 to the resonant device 1. The drive signal supplied by the generator 2 comprises a carrier signal modulated by a modulating signal which itself comprises a repetitive signal DC biased such that the index of modulation is less than 100%. The amplitude of the modulated carrier signal therefore never falls to zero.
A return signal from the resonant device 1 is coupled by coupling means 4 to a first input of a subtracting amplifier stage 5, whose second input receives a reference signal from the generator 2 via coupling means 6. The return signal comprises a modulation signal carrying information provided by the resonant device 1 but contaminated by the drive signal.
The reference signal corresponds to the drive signal, and the subtracting amplifier stage 5 is arranged to subtract this from the contaminated signal so as to provide at an output 7 a clean version of the resonant modulation signal.
An analysis and description of operation will be given for a drive signal in the form of a modulated light signal. The modulated light signal has the form:-
F (t) = A [Y + Sin (wt)]
where A is the amplitude of the light carrier wave, w is the frequency in radians, and Y is a factor representing a D.C. bias signal which is applied to the modulation signal. Although a sinusoidal modulating signal is shown for the purpose of explanation, this is not essential and other functions of time could be used.
This waveform interacts with the resonant device such that the waveform F(t) is modulated by another function F′(t). The function F′(t) has the form:
F′(t) = [1 - B (1 + Sin (wt + z))]
Where B is the amplitude and z is a phase term. This function describes the effect, on the light signal F(t), of the oscillatory movement of a resonant structure. As a result of the interaction, a waveform is produced which is the product of the two waveforms F(t) & F′(t), giving
F˝(t) = F(t).F′(t)
= A[Y + Sin (wt)].[1 - B(1 + Sin(wt + z))]
= AY[1 - B(1 + Sin(wt + z))] + A.Sin(wt)[1 - B(1 + Sin(wt + z))]
= AY(1 - B) + A (1 - B)Sin(wt) - ABY.Sin(wt + z) - AB.Sin(wt).Sin(wt + z)
The last term can be expanded resulting in,
F˝(t) = AY(1 - B) + A(1 - B)Sin(wt) - ABY.Sin(wt + z)

- $\frac{AB}{2}$
Cos(z) + $\frac{AB}{2}$
Cos(2wt + z)
By simple filtering it is possible to remove all terms except those in w, to give:
F˝(t) = A(1 - B)sin(wt) - ABY.Sin(wt + z)
Finally, subtracting a reference signal A(1 - B)Sin (wt) corresponding to the time-varying part of the modulation signal gives the resonant device modulation signal,
F˝(t) = F′(t)
= - ABY.Sin(wt + z)
The modulation signal F(t) is D.C. biased in order for the successful retrieval of the resonant device signal. The demodulation technique may thus be thought of as using amplitude modulation of a D.C. carrier. In the case of the light signal F(t) which is modulated, the D.C. biasing is arranged such that the driving signal F(t) is always on. Thus the driver may be switched between higher and lower states of light intensity but is not actually switched off.
The signal extraction apparatus shown in Figure 2 is connected to a resonant or oscillating beam transducer 10 by means of an optical fibre 11. A modulated driver 12 injects amplitude-modulated light into an optical fibre 13 connected to a first branch of a beam splitter/combiner 14, whose second branch is connected to a photodetector 15. The output of the photodetector 15 is connected to a first input of a subtracting amplifier stage 16, whose second input receives a modulating signal from the driver 12.
In use, the driver 12 generates light which is amplitude modulated at a frequency equal to the resonant frequency of the beam transducer 10. The driver ensures that the index of modulation is always less than 100%. Thus, prior to modulating the light, the modulating signal may be offset or applied with a DC bias so as to ensure that the light output by the driver never falls to zero. Light from the driver 12 passes via the optical fibre 13, the splitter/combiner 14, and the optical fibre 11 and impinges on the beam transducer 10. The transducer 10 reflects light into the optical fibre 11 and this is supplied via the splitter/combiner 14 to the photodetector 15 where the varying light is amplitude-demodulated to provide an output signal representing the amplitude of the reflected light signal. The light reflected by the beam transducer 10 into the optical fibre 11 has a first component which corresponds to the reflected drive signal ie. the modulated light from the driver 12, and a second component whose amplitude varies in accordance with the measurement signal of the transducer 10 but which has a frequency equal to the resonant frequency of the beam transducer. The subtracting amplifier stage 16 is arranged to amplify the signals at its inputs to such an extent that the amplitude of the reference signal provided by the modulating signal from the driver 12 is equal to the component of the modulating signal which contaminates the measurement signal from the transducer. Subtraction performed by the stage 16 thus removes the contaminating modulating signal so that the output 17 of the stage 16 provides a signal representing the parameter measured by the oscillating beam transducer 10. The signal extraction apparatus therefore extracts a desired signal from a combination of the desired signal and a contaminant signal of the same frequency.
The signal extraction apparatus shown in Figure 3 is similar to that shown in Figure 2, and corresponding parts are referred to by the same reference numbers. The driver is shown as comprising a voltage controlled oscillator 12a supplying the modulating signal to a light source 12b which is DC biased so as to remain on all the time. The stage 16 is also shown in more detail and comprises input stages 16a and 16b which perform an impedance buffering function, having relatively high input impedances. The output of the buffer 16a is connected to the input of an amplifier stage 16c whose output is connected to a signal inverting stage 16d. The output of the buffer amplifier 16b is connected to cascade-connected amplifier stages 16e and 16f. The outputs of the stages 16d and 16f are connected to the inputs of a summing amplifier 16g.
The main difference between the apparatus of Figure 3 and the apparatus of Figure 2 is that the reference signal is not supplied direct, eg from the voltage controlled oscillator 12a, but instead is derived from the output of the light source 12b. A beam splitter 18 divides the output of the light source between the optical fibre 13 and an optical fibre 19 connected to a further photodetector 20, whose output is connected to the input of the buffer amplifier 16b. Otherwise, the operation of the apparatus shown in Figure 3 is the same as that shown in Figure 2.
The apparatus of Figure 3 requires the presence of an additional beam splitter 18 and an additional photodetector 20 compared with the apparatus of Figure 2, and is therefore more complex and expensive. However, an advantage of the arrangement shown in Figure 3 is that the reference signal passes through the same process steps as the return signal from the transducer 10 ie it is derived from the output of the light source 12b and is subjected to photodetection in the photodetector 20. This arrangement therefore compensates for any non-linearities in the light source 12b and, provided the photodetectors 15 and 20 are substantially identical, for any non-linearities in the action of the photodetector 15. The contaminating signal can therefore be removed or suppressed more completely from the combined signal to leave a purer resonant sensor modulation signal.
Although the apparatus of Figure 3 is capable, under certain circumstances, of supplying a purer output signal, the apparatus of Figure 2 has the advantage of being simpler and cheaper to manufacture, and therefore enjoys a wider range of application. For instance, the apparatus of Figure 2 can be made sufficiently cheaply for use in automotive applications within vehicles.
Various modifications may be made within the scope of the invention. For instance, suitable means may be provided to compensate for time delays in the signals supplied to the subtracting stage. Also, any anomalies in the signal shape may be removed, for instance by bandpass filtering.
By way of example, Figure 4 illustrates in more detail a resonant sensor connected to an apparatus constituting an embodiment of the invention and comprising control electronics 30, a drive light source 31, a photodetector 32, and an optical fibre 33 connected between a sensor 34 and a Y coupler 35. The resonant sensor comprises a bridge structure or beam 36 which is suspended at its ends and which is coated with a light absorbing material for enhancing the conversion of light energy to heat at a top surface of the bridge 36. The differential thermal expansion between the top and bottom surfaces of the bridge induces a bending movement which causes the bridge to flex upwardly. By amplitude-modulating the drive light at the resonant frequency of the structure, the beam 36 oscillates mechanically at its resonant frequency. By applying stress to the structure, the resonant frequency is altered and provides a measure of the applied stress.
The structure illustrated in Figure 4 is relatively small. For instance, the bridge 36 may be of the order of 200 micrometers long, 10 micrometers wide, and 2 micrometers thick. The bridge 36 is thus compatible with single-mode and multi-mode optical fibres as the fibre 33.
The signal extraction apparatus shown in Figure 5 is connected to a resonant sensor, for instance of the type 34 shown in Figure 4, and includes an optical fibre and Y coupler 33, 35, a light source 31 such as a laser diode, and a photodetector 32 as shown in Figure 4. The control electronics comprises a phase locked loop comprising a phase sensitive detector 40, a low pass filter 41, and a voltage controlled oscillator 42. The oscillator 42 is arranged to oscillate at a frequency 2w i.e. at twice the resonant frequency of the sensor 34. The output of the oscillator 42 is connected to a first input of the phase sensitive detector 40 and to the input of a D-type flip-flop 43, which divides the oscillator frequency by 2. The output of the flip-flop 43 drives the light source 31 so as to produce drive light whose amplitude varies at a frequency equal to the resonant frequency of the sensor 34.
Light reflected from the sensor 34 is converted into a corresponding electrical signal by the photodetector 32, and contains components at frequencies w and 2w in accordance with the equations given hereinbefore. The output signal of the photodetector 32 is amplified by an amplifier 44 and supplied to a band pass filter 45 which is arranged to pass the signal component of frequency 2w and reject components of other frequencies. The output of the filter 45 is supplied to the input of an amplifier 46, whose output is connected to a phase response compensating filter 47. The filter 47 compensates for any unwanted phase errors, for instance added by the electronics of the apparatus. The output of the filter 47 is connected to a second input of the phase sensitive detector 40.
In use, the drive light from the light source 31 excites the resonant sensor 34 into resonance. Light of the same wave length reflected from the sensor is converted by the photo detector 32 into an electrical signal and the component at frequency 2w is selected by the filter 45. Following amplification and filtering by the phase response compensating filter 47, this component is compared in phase with the output signal of the voltage controlled oscillator 42. The phase locked loop quickly locks the phase and frequency of the oscillator 42 to the phase and frequency of the reflected component of modulating frequency 2w.
When the sensor 34 is subjected to stress, for instance resulting from temperature or pressure variations, its resonant frequency changes. However, the frequency of oscillation of the oscillator 42 is caused to track or follow such changes in resonant frequency by virtue of the action of the phase locked loop. The frequency of the oscillator 42 therefore provides a measure of the stress applied to the sensor 34, and the output of the oscillator 42 is used as an output of the apparatus and is connected to frequency determining means 50, such as a frequency counter, frequency analyzer, or frequency-to-voltage converter.
In the case of the sensor with the dimensions described hereinbefore with reference to Figure 4, the natural or unstressed resonant frequency of the bridge 36 is of the order of 500 kilohertz, and the voltage controlled oscillator 42 is arranged to have a free-running frequency of oscillation of approximately one megahertz.
An advantage of using the component of frequency 2w to detect changes in the reflected light signal compared with the subtraction technique described hereinbefore is that it is easier to extract the signal of frequency 2w. For instance, if the amplitude of the drive light signal is much larger than the amplitude of the portion of the reflected light signal carrying information about the property measured by the sensor, it can be difficult to subtract the signals in such as a way as to achieve a desired resolution. By monitoring the reflected component having a frequency of amplitude variation equal to twice the frequency of modulation of the drive signal, the desired resolution can be achieved.
Various further modifications are possible. For instance, the phase locked loop arrangement of Figure 5 may be replaced by the drive arrangement shown in Figures 2 and 3 and a spectrum analyzer used to scan the output of the photodetector. No external filtering is necessary and the apparatus operates in an open loop mode.

Claims

1. A signal extraction apparatus comprising means for generating a drive signal comprising a carrier signal amplitude modulated by a modulating signal, and coupling means for coupling the drive signal to a resonant sensor whose resonant frequency is substantially equal to the frequency of the modulating signal, characterised by a demodulator (15, 32) for demodulating a portion of the drive signal reflected by the sensor (1, 10, 34).

2. An apparatus as claimed in Claim 1, characterised in that the generating means comprises a modulated light source (12, 31) and the demodulator comprises a photodetector (15, 32).

3. An apparatus as claimed in Claim 2, characterised in that the coupling means comprises a light guide (11, 13, 14, 33, 35).

4. An apparatus as claimed in any one of the preceding Claims, characterised in that the generating means (2, 12,31) is arranged to amplitude modulate the carrier signal with a modulation index less than one.

5. An apparatus as claimed in any one of the preceding Claims, characterised by subtracting means (5, 16) for subtracting the modulating signal from the demodulated reflected portion of the drive signal.

6. An apparatus as claimed in Claim 5, characterised in that the subtracting means (16) are arranged to receive the modulating signal from a further demodulator (20) arranged to receive a portion of the drive signal from the generating means (12).

7. An apparatus as claimed in any one of Claims 1 to 4, characterised by frequency determining means (50) for determining changes in resonant frequency of the sensor (34).

8. An apparatus as claimed in Claim 7, characterised by a modulating signal generator comprising a voltage controlled oscillator (42) whose output is connected via a divide-by-two frequency divider (43) to the generating means (31), and a phase sensitive detector (40) having an output connected via a low pass filter (41) to a control voltage input of the oscillator (42), a first input connected to the output of the oscillator (42), and a second input connected to receive a signal component at twice the sensor resonant frequency from the demodulator (32).

9. An apparatus as claimed in Claim 8, characterised by a bandpass filter (45) for passing the signal component at twice the sensor resonant frequency.

10. An apparatus as claimed in Claim 8 or 9, characterised by a phase response compensating filter (47) connected to the second input of the phase sensitive detector (40).

11. A method of signal extraction, comprising directing onto a resonant sensor a drive signal comprising a carrier signal amplitude modulated by a modulating signal of frequency substantially equal to the resonant frequency of the sensor, and demodulating a portion of the drive signal reflected by the sensor.

12. A method as claimed in Claim 11, characterised in that the carrier signal is a light.

13. A method as claimed in Claim 11 or 12, characterised in that the index of modulation is less than one.

14. A method as claimed in any one of Claims 11 to 13, characterised in that the modulating signal is subtracted from the demodulated reflected portion of the drive signal.

15. A method as claimed in any one of Claims 11 to 13, characterised in that changes in the resonant frequency of the sensor are determined.

16. A method as claimed in Claim 15, characterised in that the frequency of the modulating signal is locked to the resonant frequency of the sensor.

17. A method as claimed in Claim 16, characterised by generating a local signal whose frequency and phase are locked to a component of the demodulated portion of the drive signal at twice the sensor resonant frequency and dividing the frequency of the local signal by two so as to generate the modulating signal.